Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Protein p120 is a proliferation-related nucleolar protein, which is detectable early in the G1-phase of the cell cycle and peaks early in the S-phase. Most human malignant tumor cells contain much higher levels of protein p120 than do normal resting cells. To learn more about p120-associated proteins, a yeast two-hybrid screen was carried out using protein p120 as the bait. Five positive clones were identified from 2 million clones for further analysis. Three of them encoded portions of the same protein, which had identity to human SRP1. The recombinant p120 and HSRP1 proteins produced in Sf9 cells are associated with each other, confirming the results of the yeast genetic assay. Protein SRP1 was originally characterized as a suppressor of RNA polymerase I mutations, and recently human SRP1 was identified as a receptor for nuclear localization sequences. In the present study, use of deletion mutations revealed that the binding of human SRP1 to p120 required the p120 nuclear localization signal (amino acids 96-119) and the C-terminus of human SRP1 (amino acids 453-491).
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PMID:Human proliferation-related protein p120 interacts with HSRP1. 921 83

Yeast Cbf5p was originally isolated as a low-affinity centromeric DNA binding protein (W. Jiang, K. Middleton, H.-J. Yoon, C. Fouquet, and J. Carbon, Mol. Cell. Biol. 13:4884-4893, 1993). Cbf5p also binds microtubules in vitro and interacts genetically with two known centromere-related protein genes (NDC10/CBF2 and MCK1). However, Cbf5p was found to be nucleolar and is highly homologous to the rat nucleolar protein NAP57, which coimmunoprecipitates with Nopp140 and which is postulated to be involved in nucleolar-cytoplasmic shuttling (U. T. Meier, and G. Blobel, J. Cell Biol. 127:1505-1514, 1994). The temperature-sensitive cbf5-1 mutant demonstrates a pronounced defect in rRNA biosynthesis at restrictive temperatures, while tRNA transcription and pre-rRNA and pre-tRNA cleavage processing appear normal. The cbf5-1 mutant cells are deficient in cytoplasmic ribosomal subunits at both permissive and restrictive temperatures. A high-copy-number yeast genomic library was screened for genes that suppress the cbf5-1 temperature-sensitive growth phenotype. SYC1 (suppressor of yeast cbf5-1) was identified as a multicopy suppressor of cbf5-1 and subsequently was found to be identical to RRN3, an RNA polymerase I transcription factor. A cbf5delta null mutant is not rescued by plasmid pNOY103 containing a yeast 35S rRNA gene under the control of a Pol II promoter, indicating that Cbf5p has one or more essential functions in addition to its role in rRNA transcription.
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PMID:The yeast nucleolar protein Cbf5p is involved in rRNA biosynthesis and interacts genetically with the RNA polymerase I transcription factor RRN3. 931 78

The c-Myc oncoprotein and its dimerization partner Max bind the DNA core consensus sequence CACGTG (E-box) and activate gene transcription. However, the low levels of induction have hindered the identification of novel Myc target genes by differential screening techniques. Here, we describe a computer-based pre-selection of candidate Myc/Max target genes, based on two restrictive criteria: an extended E-box consensus sequence for Myc/Max binding and the occurrence of this sequence within a potential genomic CpG island. Candidate genes selected by these criteria were evaluated experimentally for their response to Myc. Two Myc target genes are characterized here in detail. These encode nucleolin, an abundant nucleolar protein, and BN51, a co-factor of RNA polymerase III. Myc activates transcription of both genes via E-boxes located in their first introns, as seen for several well-characterized Myc targets. For both genes, mutation of the E-boxes abolishes transcriptional activation by Myc as well as repression by Mad1. In addition, the BN51 promoter is selectively activated by Myc and not by USF, another E-box-binding factor. Both nucleolin and BN51 are implicated in the maturation of ribosomal RNAs, albeit in different ways. We propose that Myc, via regulation of these and probably many other transcriptional targets, may be an important regulator of ribosome biogenesis.
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PMID:Myc induces the nucleolin and BN51 genes: possible implications in ribosome biogenesis. 1060 42

The aim of the present investigation was to describe the basic cell biology of the postfertilization activation of rRNA genes using in vitro-produced bovine embryos as a model. We used immunofluorescence confocal laser scanning microscopy and transmission electron microscopy to study nucleolar development in the nuclei of embryos up to the fifth postfertilization cell cycle. During the first cell cycle (1-cell stage), fibrillarin, upstream binding factor (UBF), nucleolin (C23), and RNA polymerase I were localized to distinct foci in the pronuclei, and, ultrastructurally, compact spherical fibrillar masses were the most prominent pronuclear finding. During the second cell cycle (2-cell stage), the findings were similar except for a lack of nucleolin and RNA polymerase I labeling. During the third cell cycle (4-cell stage), fibrillarin, UBF, nucleophosmin, and nucleolin were localized to distinct foci. Ultrastructurally, spherical fibrillar masses that developed a central vacuole over the course of the cell cycle were observed. Early in the fourth cell cycle (8-cell stage), fibrillarin, nucleophosmin, and nucleolin were localized to small bodies that with time developed a central vacuole. UBF and topoisomerase I were localized to clusters of small foci. Ultrastructurally, spherical fibrillar masses with a large eccentric vacuole and later small peripheral vacuoles were seen. Late in the fourth cell cycle, nucleophosmin and nucleolin were localized to large shell-like bodies; and fibrillarin, UBF, topoisomerase I, and RNA polymerase I were localized to clusters of small foci. Ultrastructurally, a presumptive dense fibrillar component (DFC) and fibrillar centers (FCs) were observed peripherally in the vacuolated spherical fibrillar masses. Subsequently, the presumptive granular component (GC) gradually became embedded in the substance of this entity, resulting in the formation of a fibrillo-granular nucleolus. During the fifth cell cycle (16-cell stage), a spherical fibrillo-granular nucleolus developed from the start of the cell cycle. In conclusion, the nucleolar protein compartment in in vitro-produced preimplantation bovine embryos is assembled over several cell cycles. In particular, RNA polymerase I and topoisomerase I are detected for the first time late during the fourth embryonic cell cycle, which coincides with the first recognition of the DFC, FCs, and GC at the ultrastructural level.
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PMID:Nucleolar proteins and nuclear ultrastructure in preimplantation bovine embryos produced in vitro. 1072 73

Current evidence suggests that the nucleolus is composed of different substructures that are dynamic and form in response to the requirement for new ribosome synthesis. Thus, agents that disrupt nucleolar organization may deregulate basic cellular events and eventually contribute to human disease. Here we report that environmentally relevant concentrations (5 microM) of inorganic mercury induce a redistribution of nucleolar protein fibrillarin from the nucleolus to the nucleoplasm in epithelial cell lines. Since treatment with transcription inhibitors led to a similar relocation of fibrillarin, the effects of mercury on transcription were studied by run-on transcription assays: mercuric ions specifically blocked synthesis of ribosomal RNA, whereas activity of RNA polymerase II remained unchanged and occurred throughout the nucleoplasm. Moreover, we show by double-labeling that inhibition of nucleolar transcription and redistribution of fibrillarin occur simultaneously, underlining that fibrillarin relocation is a consequence of the blockade of ribosomal RNA synthesis by mercury. We also detected redistribution of fibrillarin in vivo, e.g., in splenic cells of mice chronically exposed to HgCl(2). Thus, implications of this alteration of nuclear structure and function for mercury-induced autoimmunity are discussed.
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PMID:Specific inhibition of rRNA transcription and dynamic relocation of fibrillarin induced by mercury. 1094 94

In the present study immunofluorescence confocal laser scanning microscopy, autoradiography following (3)H-uridine incubation and transmission electron microscopy were used to evaluate the nucleolar protein localization, transcriptional activity, and nucleolar ultrastructure during genomic re-programming in bovine embryos reconstructed by nuclear transfer from granulosa cells into non-activated cytoplasts followed by activation. During the 1st cell cycle (1-cell embryos), no autoradiographic labelling was detected. Ultrastructurally, nucleoli devoid of a granular component were observed. During the 2nd cell cycle (2-cell embryos) autoradiographic labelling was also lacking and the embryos displayed varying degrees of nucleolar inactivation. During both the 3rd (4-cell embryos) and 4th (tentative 8-cell embryos), cell cycles autoradiographic labelling was lacking in some embryos, while others displayed labelling and associated formation of fibrillo-granular nucleoli. During the 5th cell cycle (tentative 16-cell embryos), all embryos displayed autoradiographic labelling and fibrillo-granular nucleoli. In some blastomeres, however, deviant nucleolar ultrastructure was observed. During the first cell cycle labelling of RNA polymerase I, fibrillarin, upstream binding factor (UBF) and nucleolin (C23) was localized to nuclear entities. During the 2nd cell cycle, only labelling of RNA polymerase I and fibrillarin persisted. During the 3rd and 4th cell cycle labelling of fibrillarin persisted, labelling of nucleophosmin (B23) appeared and that of nucleolin re-appeared. During the 5th cell cycle almost all embryos showed complete labelling of all proteins except for UBF, which lacked in more than half of the embryos. In conclusion, bovine granulosa cell nuclear transfer embryos showed re-modelling of the nucleoli to an inactive form followed by re-formation of fibrillo-granular nucleoli. The re-formation of fibrillo-granular nucleoli was initiated already during the 3rd cell cycle, which is one cell cycle earlier than in in vivo- and in vitro-derived bovine embryos. Moreover, in more than half of the embryos, UBF could not be immunocytochemically localized to the nucleolar compartment during the 5th cell cycle indicating lack of developmental potentials.
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PMID:Nucleolar protein allocation and ultrastructure in bovine embryos produced by nuclear transfer from granulosa cells. 1189 19

In the present study, immunofluorescence confocal laser scanning microscopy, autoradiography following (3)H-uridine incubation, and transmission electron microscopy were used to evaluate the nucleolar protein localization, transcriptional activity, and nucleolar ultrastructure during genomic reprogramming in bovine embryos reconstructed by nuclear transfer from in vitro-produced bovine morulae to activated cytoplasts. During the first cell cycle (one-cell embryos), no autoradiographic labelling was detected. Ultrastructurally, whorls consisting of densely packed fibrillar material were observed instead of nucleoli. During the second, third, and fourth cell cycle (two-, four-, and tentative eight-cell embryos), autoradiographically unlabelled nuclei contained vacuolated bodies consisting of densely packed fibrillar material. Also, during the fourth cell cycle, the first nucleoplasmic autoradiographic labelling was observed, but still without formation of fibrillo-granular nucleoli. During the fifth cell cycle (tentative 16-cell embryos), the nuclei displayed autoradiographic labelling over both nucleoplasm and presumptive nucleoli, and the formation of fibrillo-granular nucleoli was observed. In a certain proportion of blastomeres, however, abnormal patterns of nucleolar formation and apoptosis were noted. During the first two cell cycles, labelling of RNA polymerase I, fibrillarin, upstream binding factor (UBF), nucleolin (C23), and nucleophosmin (B23) was localized to nuclear entities. During the third cell cycle, labelling of topoisomerase I was observed in addition. During the fourth and fifth cell cycles, a substantial portion of the embryos presented blastomeres that lacked labelling of several of these nucleolar proteins. In conclusion, the nuclear transfer procedure was associated with remodelling of the nucleoli to an inactive form, followed by reformation of fibrillo-granular nucleoli during the fifth cell cycle. Moreover, a certain proportion of blastomeres failed to form functional nucleoli with respect to both ultrastructural organization and protein allocation.
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PMID:Nucleolar protein allocation and ultrastructure in bovine embryos produced by nuclear transfer from embryonic cells. 1190 Jun 41

DNA topoisomerase I releases torsion stress created by DNA transcription. In principle, this activity is required in the nucleoplasm for mRNA synthesis and in the nucleoli for rRNA synthesis. Yet, topoisomerase I is mostly a nucleolar protein. Current belief holds that this preference is triggered by the N-terminal domain of the enzyme, which constitutes a nucleolar import signal. Contradicting this view, we show here that nucleolar accumulation of various fragments of topoisomerase I is correlated with their lesser mobility in this compartment and not with the N-terminal domain being intact or present. Therefore, the N-terminal domain is not likely a nucleolar import signal. We show that it rather serves as an adaptor that anchors a subpopulation of topoisomerase I at fibrillar centers of nucleoli and nucleolar organizer regions of mitotic chromosomes. Thus, it provides a steady association of topoisomerase I with the rDNA and with RNA polymerase I, which is maintained in a living cell during the entire cell cycle.
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PMID:The N-terminal domain anchors human topoisomerase I at fibrillar centers of nucleoli and nucleolar organizer regions of mitotic chromosomes. 1211 95

The aim of this study was to describe the dynamic changes in the localization of the key nucleolar protein markers, fibrillarin, B23/nucleophosmin, C23/nucleolin, protein Nopp140, during the final stages of bovine oocyte growth. All these proteins were present in the large reticulated nucleoli of oocytes from the small-size category follicles (<1 mm). The entire nucleolus exhibited strong positivity for UBF (upstream binding factor, RNA polymerase I-specific transcription initiation factor), which displayed a dotted staining pattern. In contrast, protein p130 was diffusely distributed throughout the nucleus and excluded from nucleoli. In oocytes approaching the late period of growth (2-3-mm follicles), UBF localization shifted to the nucleolar periphery. Double staining of UBF-p130 revealed a gradual accumulation of p130 at the periphery shell around the nucleolus. In fully grown oocytes (>3-mm follicles), all studied nucleolar proteins were detected in the small compact nucleoli. The cap structure, attached to the compact nucleolus surface, was positive for UBF and PAF53 (subunit of RNA polymerase I). The UBF-positive cap showed a close structural association with p130. It is concluded that, during the process of oocyte nucleolus compaction, UBF and PAF53, proteins involved in the rDNA transcription, are segregated from fibrillarin and Nopp140, proteins essential for early steps of pre-rRNA processing. The observed changes may reflect the transition from pre-rRNA synthesis to pre-rRNA processing as an analysis of the relative abundance of the developmentally important gene transcripts confirmed. In addition, discovered structural association between UBF and p130 suggests a role for pocket proteins in ribosomal gene silencing in mammalian oocytes.
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PMID:Immunolocalization of upstream binding factor and pocket protein p130 during final stages of bovine oocyte growth. 1461 6

The soluble fraction of nuclear proteins is a functionally significant fraction, since it has been shown that it contains ribonucleoproteins active in nuclear RNA metabolism. The aim of this work was to detect variations associated with cell proliferation, by comparing two-dimensional proteomes obtained from the soluble fractions of onion nuclei isolated from actively proliferating root meristematic cells versus nonmeristematic root cells. In particular, we have studied the physicochemical features of the major nucleolar protein NopA100, a highly phosphorylated, nucleolin-like protein. A total of 384 spots were quantified in meristematic nuclei, while only 209 were detected in nonmeristematic nuclei. The comparison of both proteomes resulted in the determination of specific spots for each proliferative state and those which were common to both cases. Furthermore, among these latter, we could discriminate quantitative differences. Interestingly, well-known nucleolar proteins, such as RNA polymerase I, B23 and the nucleolin-like protein NopA100, were significantly increased in proliferating cells. Western blots with anti-NopA100 antibody demonstrated 26 spots in the meristematic sample. All the spots detected were clustered at 100 kDa and were distributed through an isoelectric point (pI) range of 4.3-6.6. In contrast, only seven spots were found in the extract from nonmeristematic nuclei, and the pI range was shortened to 4.8-6.1. These results indicate that the state of NopA100 phosphorylation correlates with the degree of nucleolar activity, i.e. the protein is more highly phosphorylated in cycling cells. We have also analyzed the bidimensional silver staining of the nucleolar organizing region (Ag-NOR) pattern of the soluble nuclear fraction in order to identify plant cell phosphoproteins that are considered to be markers of proliferation. These experiments demonstrated that NopA100, the onion, nucleolin-like protein, is an Ag-NOR protein. In addition we found that the plant homologue of the vertebrate nucleolar phosphoprotein B23 migrated as two clusters of acidic spots, 43 and 42 kDa respectively in molecular mass. The differences between these features and those described for mammalian cells is discussed. Our results demonstrate that the use of protein fractionation procedures with functional significance and the location of candidate spots by indirect techniques are advantageous, complementary methods to random selection procedures for proteomic studies involving further mass spectrometry analysis.
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PMID:Identification of specific plant nucleolar phosphoproteins in a functional proteomic analysis. 1476 Jul 10


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